DE69734346T2 - Device for terminating an optical path - Google Patents

Description

background the invention

technical area

The The present invention relates to techniques for enabling synchronous digital hierarchy (SDH) signals. in an optical route network. It particularly concerns the transformation between transmitted on the electrical level SDH signals and transmitted at the optical level Signals of an optical path.

general State of the art

techniques Wavelength Division Multiplexing (WDM), which fully exploit the broadband nature of light, and optical path networks that use wavelength routing in the path layer introduce, have both are experiencing rapid development. It could be assumed that existing SDH, ATM and PDH networks (plesiochronous digital hierarchy) all possible in optical path networks. PDH networks however, they are currently being replaced by SDH networks and most of them The ATM networks are SDH based systems that Enable ATM cells in SDH paths. The central task is therefore to enable SDH signals in optical path networks.

1 serves for a simple explanation of a conventional switched network connecting subscriber terminals. Attendees 11 and 18 are about mediation 12 , the transit agency 13 , Line termination equipment 14 and 15 the transit agency 16 and the mediation 17 connected. Attendees 11 and the mediation 12 are connected by a 64 kb / s channel, for example, and the same applies to the switch 17 and the participant 18 , The mediation 12 , the transit agency 13 and the line termination 14 (and the line termination 15 , the transit agency 16 and the mediation 17 ) are connected by, for example, 52 Mbit / s paths comprising 64 kb / s temporally multiplexed channels. In the transmission between the line terminations 14 and 15 another multiplexing of these paths takes place.

2 serves to explain the connection of SDH signal paths via an SDH path crossconnect. The transit agencies 21-1 to 21-4 are each about line terminations 22-1 to 22-4 and 23-1 to 23-4 with the SDH path crossconnect 25 connected. 2 shows a single way from the transit exchange 21-1 to each of the transit agencies 21-2 to 21-4 , and in general, the transmission between the line terminations 22-1 to 22-4 and 23-1 to 23-4 executed on the basis of time-multiplexed paths, with the direction of individual paths through the SDH crossconnect 25 is set.

3 serves as an illustration of how part of the 2 shown path links in an optical path network is realized. In this case, terminations will be used instead of line terminations 26-1 to 26-3 used an optical path and these terminations 26-1 to 26-3 of the optical path are each via wavelength division multiplexed links with the optical path crossconnect 27 connected. Optical paths can be as desired between the degrees 26-1 to 26-3 of the optical path, and these optical paths are enabled in the wavelength division multiplexed links by using WDM techniques. A detailed discussion of such optical path networks is described, for example, in K. Sato and S. Okamoto, "Evolution of Path Layer Techniques Toward Photonic Networks", IEICE Japan Autumn Meeting, September 1992, SB-7-1, and in K. Sato, S. Okamoto and H. Hadama, "Optical Path Layer Technologies to Enhance B-ISDN Performance", Proc. IEEE ICC'93, June 1993, pages 1300-1307.

One An optical path signal includes a main signal and a monitor signal of the optical path. There are two types of signal as the monitoring signal used. The first type is a monitoring signal of the optical Way, that at the electrical level in the same frequency band how the main signal is multiplexed. This species is mainly used for monitoring the quality of the main signal used. The second type is an optically added monitoring signal of the optical path, which is at the optical level in one of the Main signal of different frequency band multiplexed or the main signal through one of the for the main signal used different modulation superimposed becomes. This second type is mainly used for administration and identification the type of main signal used. (See S. Okamoto, K. Oguchi and K. Sato, "Network architecture and management concepts for optical transport networks ", Proceedings on IEEE / IFIP 1996 Network Operations and Management Symposium (NOMS '96), pages 1-11, April 1996, and Japanese Patent Application 8-49751, "Method for supervision of wavelength multiplexed optical communications ", (at the time of the registration of the present application not yet disclosed).

Thus, when a signal of an optical path is wavelength-multiplexed and transmitted through WDM links, an optical-path supervisory signal and a wavelength-division multiplexed optical-path supervisory signal are transmitted together with it Watching signals are partially contained in the signal of the optical path. The optical path supervisory signal and the wavelength division multiplexed optical path supervisory signal are monitored, and if an error occurs in an optical fiber or in certain transmission devices, restoration is performed. the optical path along a route that leads around the location of the error, a path recovery performed.

The Document EP-A-0 543 327 deals with overhead insertion in the conversion of electrical into optical.

The Writings HWU C ET AL .: "INTERNATIONAL GATEWAY FOR SDH AND SONETINTERCONNECTION "PROCEEDINGS OF THE GLOBAL TELECOMMUNICATIONS CONFERENCE (GLOBECOM), NEW YORK, US, IEEE, PAGES 725-734, XP000488638 ISBN: 0-7803-1821-8 AND BRATE S ET AL .: "SDH / SONET INTERWORKING: END-TO-END SDHSERVICES PROVIDED OVER SONETRINGS ", PROCEEDINGS OF THE ANNUAL CONFERENCE ON EUROPEAN FIBER OPTIC COMMUNICATIONS AND NETWORKS (EFOC), XP000603568 discuss the conversion of SDH into SONET.

It will now be an explanation of the SDH transmission scheme given. In SDH transmission is the unit of information transfer the virtual container (VC), the one useful signal (to be transmitted Information) and a "way overhead" that added to this useful signal becomes. When VC signals in a transmission medium how to enable such as an optical fiber is one as "synchronous Transfer module "(below STM) formed frame. It will be a signal of administrative Unit (AU) formed by first pointer (AU pointer) to the VC signals added be to differences in the synchronization of the VC signals with respect to manage the STM frame, and then time the VC signals be multiplexed. By time multiplexing N of these AU signals and adding a partial monitoring signal an STM-N signal is formed. After conversion of electrically into optically, this STM-N signal is sent to the optical fiber. In the receiving terminal is the reverse processing is performed (see the ITU-T Recommendation G.707, "Digital transmission system - terminal Equipments - General ", and ITU-T Recommendation G.783," Characteristics of synchronous digital hierarchy (SDH) equipment functional blocks "). When SDH signals in wavelength multiplexed Transfer form Become a variety of STM-N signs after conversion to optical Transmit signals of different wavelengths.

If at a certain location in the transmission medium or in certain transmission devices Error occurs by re-routing VCs around the location of the error performed a path recovery around. It is conditional that if an error occurs, the termination devices next to the fault location synchronization with respect to the frame maintained by STM-N or VC signals in which each bit is a logical "1" and in which this is a substitute for the lost one Signal to be used. Because the SDH path monitoring signals in the VCs no valid ones Values can In this case, errors are rerouted in individual VCs and in subsequent VCs be recognized.

The conventional signal format for enabling an SDH signal in an optical path network will be described with reference to FIG 4 to 7 explained. 4 shows the format of a VC signal, 5 the format of an STM-N signal, 6 the format of an AU signal and 7 the format of a signal of the optical path. In these signal format diagrams, the direction of time is from left to right along the horizontal axis. The signals are read not only from left to right, but also vertically, so that reading starts in the upper left corner of the frame and ends in the lower right corner (all subsequent drawings showing a signal format follow this pattern).

Different sizes of virtual containers are defined, each of which can provide a different transfer rate. These various VCs are known as VC-11, VC-12, VC-2, VC-3, VC-4, VC-4-4c and VC-4-16c. 4 shows the format of a VC-4 signal. As can be seen, this comprises a 260 × 9 byte payload area P and a 9 byte way monitor area P0. An STM-N signal comprises multiplexed VC signals of this type. More specifically, as in 5 For example, an STM-N signal has a 9 × (261 × N) byte payload signal range, a 3 × (9 × N) byte sub-monitor signal range S1, a 5 × (9 × N) byte sub-monitor signal range S2 and a 1 × (9 × N) byte AU pointer range a.

The Signal format of a conventional An optical path signal is included in that of an STM-N signal different from the SDH transmission scheme. When transferring an SDH signal through an optical communications network It is therefore necessary to convert the SDH signal format into a signal format of the optical path.

Namely, if an STM-N signal in an optical path to be enabled, the signal must be extended and its transmission speed be increased so that, as in 7 1, a monitoring signal range of the optical path can be provided and a monitoring signal of the optical path can be inserted therein.

There is also the problem that, if an error occurs in the optical communication network, two Types of way-recovery are needed, namely alternative Routes of optical paths in the optical communications network and alternative Routing VC signals in the SDH. As a result, more network resources needed.

The The present invention has been conceived in view of this situation and an object of the present invention is the provision of signal termination devices an optical path with the ability a monitoring signal of the optical path without adding an increasing signal length.

Short illustration the invention

According to one The first aspect of the present invention includes signal termination devices an optical path, for example, for use as the transmission terminal of a termination means the optical path, the following: an electrical signal termination means to complete one or more SDH signals transmitted by electrical signals and to output a signal to be sent to the optical path electrical signal; and an optical path termination means for feeding a monitoring signal of the optical path at the electrical level in this electric Signal, to convert the resulting signal into an optical one Signal and outputting this signal as the signal of the optical path; the closure means the optical path means for feeding the monitoring signal the optical path instead of the monitoring signal contained in the SDH signal of the SDH part.

The electrical signal termination means preferably comprise: one or more processing means the monitoring signal or the monitoring signals the SDH part included in the one or more SDH signals; one or more demultiplexing means for demultiplexing the SDH signal or SDH signals processed in this way whereby it is converted into a plurality of VC signals, and multiplexing means for multiplexing the plurality of ones of these or these demultiplexing means output VC signals, to convert these into AU signals Add from AU pointers to further multiplexing of the plurality of AU signals thus obtained and the Outputting an electrical signal having a signal format of the optical Way. The feeding means feeds said monitoring signal of the optical Path preferably at the electrical level in a predetermined Range of this electrical signal with a signal format of the optical Away. In particular, it preferably feeds the monitoring signal the optical path at the electrical level in a range one, which is the area for the monitoring signal of the SDH part in the SDH signal format (referred to as "partial overhead").

It is feasible, several means of closure of the optical path, according to each of these several termination means the optical path to provide a multiplexer and between these multiplexing means and said demultiplexing means to provide a switching circuit for switching signals. Besides that is it feasible a plurality of multiplexing means and optical path terminating means but the switching circuit for switching signals between the outputs the multiplexer means and the inputs of the terminating means to provide the optical path.

The termination means of the optical path preferably means for adding a monitoring signal the optical path to the signal of the optical path on the optical Level, this signal from the monitoring signal of the optical Path is disconnected on the electrical level. This add-on can be configured to do it the signal of the optical path and the monitoring signal of the optical path wavelength-multiplexed at the optical level, or it can be configured to use one of those used for the main signal applies separate modulation to the signal of the optical path.

According to a second aspect of the present invention, optical path signal termination devices for use, for example, as the reception port of an optical path terminator include: optical path termination means for receiving a signal of the optical path and converting it into an electrical signal; and electrical signal terminating means for converting the electrical signal output from said optical path terminating means into one or more SDH signals and outputting the same; wherein the signal of the optical path has a signal format which does not include the SDH signal monitoring part of the SDH signal, and the electrical signal termination means comprises one or more means each for monitoring a signal of the SDH part instead of the one detected by the terminating means of the SDH part optical path received Si gnal the optical path contained monitoring signal of the optical path.

The termination means of the optical path preferably a means that, after the signal of the optical path was converted into an electrical signal, the monitoring signal of optical path at the electrical level corresponding to the predetermined Range of the electrical signal was added, extracted. The electric Signal termination means comprises preferably: demultiplexing means for demultiplexing the the closing means the optical path output electrical signal, causing this is converted into several VC signals; Multiplexer means for converting the multiple VC signals output from these demultiplexing means in AU signals by multiplexing this and adding AU pointers; and means for respectively adding overheads of the SDH part to the AU signals output from these multiplexing means.

The monitoring signal of the optical path at the electrical level becomes in the area of the monitor signal of the SDH part in the SDH signal format added to the signal of the optical path. The closing agent of the optical path can be configured so that an electric Outputs signal with a signal format of the optical path, wherein the electrical signal of this monitoring signal of the optical path at the electrical level. The electrical signal termination means can also comprising: demultiplexing means for demultiplexing the the closing means the optical path output electrical signal (the electrical signal the monitoring signal of the optical path at the electrical level), whereby in several VC signals is converted; Means for respectively rewriting the monitoring signal areas of the SDH way, which in the plurality of VC signals output from these demultiplexing means become; Multiplexer means for multiplexing the output signals of these Rewriting means and converting them to AU signals by adding AU pointers; and means for adding monitoring signals of the SDH part to the AU signals output from these multiplexing means.

It is feasible, several means of closure of the optical path, according to each of these several termination means the optical path to provide a demultiplexer and between these demultiplexing means and said multiplexing means to provide a switching circuit for switching signals. Furthermore is it feasible several means of closure of the provide optical path and multiple demultiplexer means, but the switching circuit for switching signals between the outputs of these several means of closure the optical path and the entrances the multiple demultiplexer means.

The termination means of the optical path preferably means for separating the monitoring signal of the optical Way from the signal of the optical path at the optical level, this signal being from the monitoring signal the optical path is separated at the electrical level.

A termination means of the optical path may include a plurality of said signal termination devices of the optical path for use as transmission ports and can with a wavelength division multiplexer equipped that each of these several signal termination devices of the optical path allocates an optical carrier of different wavelengths, their respective optical output signals wavelength division multiplexed and send the result to the optical transmission line. A closure device The optical path may also include a plurality of said signal termination devices of the optical path for use as receiving ports and can be equipped with a wavelength demultiplexer That is, that each of these several optical signal termination devices Way an optical carrier different wavelength allocates, the wavelength multiplexed demultiplexes optical signals from the optical transmission line and the results to the multiple signal termination devices of the optical Way out.

Short collected provide the preferred embodiments the invention signal termination devices of the optical path, that between a transmitted at the electrical level SDH signal and an optical signal transmitted at the optical level Transform way, a monitoring signal feed the optical path into the signal of the optical path, without the signal length to enlarge, and the monitoring signal range of the SDH part included in the SDH signal as the area for the monitoring signal the optical path used in the signal of the optical path.

Short description the drawings

1 serves as a simple explanation of a conventional switched network connecting subscriber terminals.

2 serves to explain the path connection of SDH signals via an SDH crossconnect.

3 serves to explain how certain of the 2 would be implemented in an optical path network.

4 shows the format of a VC signal.

5 shows the format of an STM-N signal.

6 shows the format of a conventional AU signal.

7 shows the format of a conventional signal of the optical path.

8th Fig. 10 is a block diagram of optical path signal termination devices according to a first embodiment of the present invention.

9 shows the format of an optical path signal according to the present invention.

10 FIG. 14 shows an example of a configuration for superimposing an optical path supervisory signal on the optical level via an optical path signal.

11 Fig. 14 shows an example of another configuration for superimposing an optical path supervisory signal on the optical level via an optical path signal.

12 Fig. 12 is a block diagram of optical path signal termination devices according to a second embodiment of the present invention.

13 Fig. 12 is a block diagram of optical path signal termination devices according to a third embodiment of the present invention.

14 FIG. 10 is a block diagram of optical path signal termination devices according to a fourth embodiment of the present invention. FIG.

15 Fig. 12 is a block diagram of optical path signal termination apparatuses according to a fifth embodiment of the present invention.

16 Fig. 10 is a block diagram of optical path signal termination devices according to a sixth embodiment of the present invention.

17 Fig. 10 is a block diagram of optical path signal termination apparatuses according to a seventh embodiment of the present invention.

18 Fig. 12 is a block diagram of optical path signal termination apparatuses according to an eighth embodiment of the present invention.

19 Fig. 12 is a block diagram of optical path signal termination devices according to a ninth embodiment of the present invention.

Full Description of preferred embodiments

The configuration of a first embodiment of the present invention will be described with reference to FIG 8th and 9 explained. 8th FIG. 12 is a block diagram of optical path signal termination devices according to the first embodiment. FIG 9 shows the format of an optical path signal according to the present invention.

This embodiment serves as a transmission terminal of a terminator of the optical path. In order to terminate one or more SDH signals transmitted by electrical signals and to output an electrical signal to be transmitted to an optical path, it comprises: input lines 111 - 114 to which the SDH signals arrive; processing circuits 121 - 124 for monitoring signals of the SDH part to complete these SDH signals and to process the monitoring signals of the SDH part contained therein; demultiplexer circuits 131 - 134 for demultiplexing the output signals of these processing circuits 121 - 124 for monitoring signals of the SDH part, whereby these are converted into a plurality of VC signals; and a multiplexer circuit 141 for converting the plurality of these demultiplexer circuits 131 - 134 output VC signals into AU signals by multiplexing them and adding AU pointers and then further multiplexing the plurality of AU signals obtained thereby and outputting an electrical signal in the signal format of the optical path. In order to convert this electrical signal into an optical signal for output to the optical path, this embodiment additionally comprises a first monitoring signal feed-in circuit 211 the optical path for inputting a monitoring signal of the optical path at the electrical level instead of the monitoring signal of the SDH part contained in the SDH signal; a conversion circuit 212 from electrical to optical for converting the electrical signal in the signal format of the optical path, to which a monitoring signal of the optical path on the elek added to a visual signal; a second monitoring signal feed-in circuit 213 the optical path for adding a monitoring signal of the optical path at the optical level, which is separated from the monitoring signal of the optical path at the electrical level, to the signal of the optical path; and a monitoring signal controller 214 of the optical path for controlling the addition and multiplexing of optical path supervisory signals by the first and second monitor signal feed circuits 211 and 213 of the optical path.

As in 5 shown in the SDH signal input lines 111 - 114 inputted SDH signals (ie, STM-N signals) of 9 × (270 × N) data bytes, respectively, which are divided into the following ranges: sub-supervisory signal area S1 (3 × (9 × N) bytes), sub-supervisory signal area S2 ( 5 × (9 × N) bytes), AU pointer area a (1 × (9 × N) bytes) and payload area P (9 × (261 × N) bytes). The monitoring signal processing circuits 121 - 124 of the SDH part carry out the necessary processing for reading the data of the sub-monitoring signal areas S1 and S2. This processing is defined in ITU-T Recommendation G.708, "Network node interface for the synchronous digital hierarchy".

Those of the monitoring signal processing circuits 121 - 124 SDH signals processed in the SDH part are put into the demultiplexer circuits 131 - 134 entered.

Each demultiplexer circuit 131 - 134 demultiplexes an STM-N signal into N signals, from which it extracts and outputs only the payload area P (the VC signal) (9 × 261 bytes). In the illustrated example, an STM-4 signal enters each of the SDH signal input lines 111 - 114 that is, from each demultiplexer circuit 131 - 134 four useful signal (VC) signals are output.

Those of the demultiplexer circuits 131 - 134 demultiplexed useful signal signals are in the multiplexer circuit 141 entered. The multiplexer circuit 141 adds AU pointers to the sixteen input wanted signals. As in 6 4, the format of a signal to which AU pointers have been added (ie, an AU signal) includes four regions: an undefined region U1, an undefined region U2, an AU pointer region a, and a payload region P. The multiplexer circuit 141 also performs byte interleaved multiplexing of the sixteen AU signals.

The output signal of the multiplexer circuit 141 enters the monitoring signal feed circuit 211 entered the optical path. The monitoring signal feed circuit 211 of the optical path inserts in the input signal a monitoring signal of the optical path resulting from the monitoring signal control 214 the optical path was sent. The resulting signal is passed through the conversion circuit 212 converted from electrical to optical from an electrical signal into an optical signal. The monitoring signal feed circuit 213 of the optical path then inserts in this optical signal a monitoring signal of the optical path, which consists of the monitoring signal control 214 the optical path was sent.

As in 9 shown comprises a signal of the optical path, which consists of the monitoring signal feed circuit 211 of the optical path, the following four areas: the optical path supervisory signal areas O1 and O2, the AU pointer area a, and the payload area P. In this example, N, the number of multiplexed VC signals is sixteen.

In this embodiment, a circuit which multiplexes SDH signals serves as a multiplexer circuit 141 , Consequently, the signal of the optical path has the format of an SDH signal, except that instead of a monitoring signal of the SDH part, an optical-path supervisory signal is input. The present invention may also be implemented using other formats for the multiplexer circuit 141 executed multiplexes are implemented as long as the signal format used corresponds to this. The important point is that instead of a monitoring signal of the SDH part, a monitoring signal of the optical path is fed.

The conversion circuit 212 from electrical to optical may set different wavelengths for the optical output signal and may be implemented by, for example, a tunable wavelength laser. However, it is also feasible to use a fixed wavelength for the optical output signal.

With respect to feeding by the monitoring signal input circuit 213 of the optical path of the optical path monitoring signal at the optical level, an optical signal of a wavelength different from the wavelength of the main signal may be used, or a modulation different from that of the main signal may be applied to the optical path signal. Examples of these possibilities are in 10 and 11 shown. At the in 10 configuration shown produces a La serdiode 311 a duration output and an optical modulator 312 uses the main signal to modulate this CW. In this case, the monitoring signal of the optical path at the optical level by superimposing on the drive signal, which in the laser diode 311 is entered. At the in 11 configuration shown is the laser diode 313 directly modulated by the main signal. Also in this case, the monitoring signal of the optical path at the optical level can be added by placing it in the laser diode 313 is superimposed input drive signal.

12 Fig. 12 is a block diagram of optical path signal termination devices according to a second embodiment of the present invention. The distinguishing feature of this second embodiment is that by adding the switching circuit 611 to the first embodiment, the SDH signals can be rerouted.

The operation of the SDH signal input lines 111 - 114 , the monitoring signal processing circuits 121 - 124 the SDH part and the demultiplexer circuits 131 - 134 is the same as that in the first embodiment of the present invention.

The spatial positions of the demultiplexer circuits 131 - 134 output useful signals (ie, VC signals) may be provided by the switching circuit 611 be moved. Since this second embodiment uses a 16x16 switch, it can pass the sixteen VC signals between the multiplexer circuit in any desired manner 621 and the multiplexer circuit 622 to distribute.

The through the switching circuit 611 distributed payload signals are passed through the multiplexer circuits 621 and 622 multiplexed. These multiplexer circuits 621 and 622 Add AU pointers to each of the eight payload signals that were specified. In addition, the multiplexer circuits lead 621 and 622 byte interleaved multiplexing of the resulting eight AU signals.

The output signals of the multiplexer circuits 621 and 622 each become the signal termination circuits 631 and 632 the optical path of the transmission port sent. The signal termination circuits 631 and 632 the optical path of the transmission terminal each comprise a monitoring signal input circuit 211 the optical path, a conversion circuit 212 from electrical to optical, a monitoring signal feed circuit 213 of the optical path and a monitoring signal control shown in the first embodiment 214 of the optical path and perform the following processing on the output of the multiplexer circuit 621 respectively. 622 by: feeding in optical signals at the electrical level, converting from electrical to optical, and adding optical path monitoring signals at the optical level. The results of this processing are then sent to the signal output lines 641 and 642 of the optical path are output as signals of the optical path.

By demultiplexing the input SDH signals into VC signals and providing a switching circuit capable of switching these VC signals, it is possible to configure optical path signal termination devices that provide a switching function at the VC signal level. Consequently, in the case of one in the signal output line 641 or 642 optical path error, the transmission path for the optical path signal is quickly switched.

13 Fig. 12 is a block diagram of optical path signal termination devices according to a third embodiment of the present invention. The distinguishing feature of this embodiment is that by using the switching circuit 711 for performing switching after the VC signals have been multiplexed, the optical path terminators can be configured using a smaller switch.

The operation of the SDH signal input lines 111 - 114 , the monitoring signal processing circuits 121 - 124 the SDH part and the demultiplexer circuits 131 - 134 agrees with that in the first embodiment.

Those from the demultiplexer circuits 131 - 134 output useful signals (ie, VC signals) are provided by the multiplexer circuits 621 and 622 multiplexed. Namely, the multiplexer circuits add 621 and 622 the eight input useful signal signals each add AU pointers and then perform a byte-interleaved multiplexing of the resulting eight AU signals.

The spatial positions of the signals generated by the multiplexer circuits 621 and 622 may have been multiplexed by the switching circuit 711 be switched. The switching circuit 711 differs in this respect from the switching circuit 611 in that it does not switch VC signals but instead the output signals of the multiplexer circuits 621 and 622 switches.

The output signals of the switching circuit 711 become the signal termination circuits 631 and 632 the optical path of the transmission port sent. These signal termination circuits 631 and 632 The optical path of the transmitting terminal each comprise a first monitoring signal input circuit 211 the optical path, a conversion circuit 212 from electrical to optical, a second monitoring signal feed circuit 213 of the optical path and a monitoring signal control shown in the first embodiment 214 of the optical path and respectively carry out the following processing on the output signals of the switching circuit 711 by: feeding in optical signals at the electrical level, converting from electrical to optical, and adding optical path monitoring signals at the optical level. The results of this processing are called optical path signals on the signal output lines 641 and 642 of the optical path.

Since this third embodiment, a 2 × 2 switch as a switching circuit 711 It can be used from the SDH signal input lines 111 and 112 input SDH signal group and those from the SDH signal input lines 113 and 114 entered SDH signal group in any desired manner between the two signal output lines 641 and 642 distribute the optical path. For the switching circuit 711 For example, a larger switch may be used in accordance with an eventual increase in the number of SDH signal input lines and / or signal output lines of the optical path. Even if so a bigger switch 711 must be used, it is also possible to use a switch with fewer inputs and outputs than the switching circuit 611 used in the second embodiment.

14 Fig. 12 is a block diagram of optical path signal termination devices according to a fourth embodiment of the present invention, particularly showing the configuration of optical path signal termination devices for a receive port which converts a signal of the optical path into SDH signals.

These optical path signal termination devices include: a supervisory signal extraction circuit 812 the optical path for separating the monitoring signal of the optical path at the optical level from the signal of the optical path, a conversion circuit 813 from optical to electrical for converting this signal of the optical path into an electrical signal, a monitoring signal extracting circuit 814 of the optical path for extracting the monitoring signal of the optical path at the electrical level from the signal of the optical path, which has been converted into an electrical signal, a monitoring signal control 815 of the optical path for processing the optical path monitoring signals at the optical level and the electrical level, a demultiplexer circuit 911 for demultiplexing by the monitoring signal extracting circuit 814 the optical path output electrical signal and converting it into a plurality of VC signals, multiplexer circuits 921 - 924 for multiplexing the plurality, by this demultiplexer circuit 911 output VC signals and convert them to AU signals by adding AU pointers and monitoring signal injection circuits 931 - 934 of the SDH part for feeding monitoring signals of the SDH part into the multiplexer circuits 931 - 924 output AU signals and output the resulting signals to the SDH signal output lines 941 - 944 ,

The monitoring signal extraction circuit 812 of the optical path demodulates the monitoring signal of the optical path, which at the optical level that from the signal input line 811 The signal of the optical path inputted to the optical path has been superimposed. When the optical path supervisory signal has been wavelength division multiplexed onto the optical path signal, this demodulation is performed after the wavelength demultiplexing. When the monitoring signal of the optical path has been superimposed by applying modulation different from that of the signal of the optical path, the demodulation is performed after the branching of the optical signal. Thereby, the monitoring signal of the optical path can be demodulated without destroying the useful signal range forming the main signal. The demodulated monitor signal of the optical path then becomes the monitor signal controller 815 sent the optical path.

The conversion circuit 813 from optical to electrical, the signal of the optical path, after passing through the monitor signal extraction circuit, converts 812 the optical path has been processed into an electrical signal.

The monitoring signal extraction circuit 814 of the optical path extracts the monitoring signal of the optical path in the in 9 shown monitoring signal ranges O1 and O2 of the optical path from the by the conversion circuit 813 from optically into electrically output electrical signal and sends it to the monitoring signal control 815 of the optical path. After this extraction are the over undefined optical signal ranges O1 and O2 of the optical path and can be used as a container for any type of data.

The demultiplexer circuit 911 demultiplexes the payload portions of the monitor signal extraction circuit 814 of the optical path and outputs the result as individual VC signals. In this example, it is assumed that the demultiplexer circuit 911 converts its input signal into sixteen VC signals.

The multiplexer circuits 921 - 924 each multiplex a plurality of VC signals (four in this example) from the demultiplexer circuit 911 which are first converted to AU signals by adding AU pointers and then performing far-multiplexed multiplexing and outputting the result.

The monitoring signal input circuits 931 - 934 of the SDH part add to the output of the multiplexer circuits 921 - 924 each add a monitoring signal of the SDH part and give the result as an SDH signal to the SDH signal output lines 941 - 944 out. In this embodiment, SDH signals in the in 5 shown STM-N signal format output with N = 4.

15 Fig. 12 is a block diagram of optical path signal termination apparatuses according to a fifth embodiment of the present invention. This embodiment comprises: two signal input lines 1011 and 1012 the optical path; two signal termination circuits 1021 and 1022 the optical path of the receiving terminal, each having a monitoring signal extraction circuit 812 of the optical path, a conversion circuit 813 from optical to electrical, a monitoring signal extraction circuit 814 the optical path and a monitoring signal control 815 of the optical path and two demultiplexer circuits 1031 and 1032 , each of the demultiplexer circuit 911 same. This fifth embodiment is different from the fourth embodiment in that it also includes the switching circuit 1041 by which the converted from the signal of the optical path VC signals can be switched.

The operation of the signal termination circuits 1021 and 1022 the optical path of the receiving terminal and the demultiplexer circuits 1031 and 1032 agrees with that in the fourth embodiment. The spatial positions of the demultiplexer circuits 1031 and 1032 output VC signals can by the switching circuit 1041 be moved. Since this fifth embodiment uses a 16x16 switch, it can multiplex the sixteen VC signals in any desired manner between the multiplexer circuits 921 - 924 to distribute.

The VC signals generated by the switching circuit 1041 are distributed by the multiplexer circuits 921 - 924 are multiplexed in the same manner as in the fourth embodiment, and after the monitoring signal feed circuits 931 - 934 of the SDH part have added monitoring signals to the SDH part, from the SDH signal output lines 941 - 944 output.

As explained above So it is by demultiplexing the signal of the optical Way to VC signals and providing a switching circuit capable of switching these VC signals possible, Signal termination equipment of the optical path to configure a switching function at the VC signal level Offer.

16 Fig. 10 is a block diagram of optical path signal termination devices according to a sixth embodiment of the present invention. By performing the switching in the switching circuit 1111 prior to demultiplexing into VC signals, this embodiment can configure the optical path terminators with a smaller switch.

The operation of the signal input lines 1011 and 1012 the optical path and the signal termination circuits 1021 and 1022 of the optical path of the reception terminal is the same as that in the fifth embodiment.

The spatial positions of the signal termination circuits 1021 and 1022 signals output from the optical path of the receiving terminal can be detected by the switching circuit 1111 be moved. Since this sixth embodiment, a 2 × 2 switch as a switching circuit 1111 it can do that from the signal input line 1011 the optical path input signal of the optical path and the signal input line 1012 optical path signal inputted in any desired manner between the two SDH signal output line groups (ie the SDH signal output lines) 941 and 942 and the SDH signal output lines 943 and 944 ) to distribute.

The from the switching circuit 1111 to the demultiplexer circuits 1031 and 1032 transmitted signals are converted into VC signals. These VC signals are passed through the multiplexer circuits 921 - 924 multiplexed, and after the monitoring signal injection circuits 931 - 934 Of the SDH part have added monitoring signals of the SDH part, they are from the SDH signal output lines 941 - 944 output.

17 Fig. 10 is a block diagram of optical path signal termination apparatuses according to a seventh embodiment of the present invention. This embodiment enables flexible network operation by adding supervisory signal rewriting circuits 1211 - 1226 of the SDH path to the fourth embodiment.

The operation of the signal input line 811 the optical path; the signal termination circuit of the optical path of the receiving terminal 821 with the monitoring signal extraction circuit 812 the optical path, the conversion circuit 813 from optical to electrical, the monitor signal extraction circuit 814 the optical path and the monitoring signal control 815 the optical path and the demultiplexer circuit 911 agrees with that in the fourth embodiment.

The sixteen from the demultiplexer circuit 911 outputted VC signals are converted into respective supervisory signal rewrite circuits 1211 - 1226 entered the SDH path. In this patent application, the VC signals may in principle be any of the VC-3, VC-4, VC-4-4c and VC-4-16c, but the following explanation applies to VC-4 signals. As in 4 As shown, a VC-4 signal includes a path monitoring signal area PO (9 bytes) and a payload area P (9 × 260 bytes). The supervisory signal rewriting circuits 1211 - 1226 of the SDH path are circuits for setting an externally given desired value for the path monitoring signal area PO.

VC signals whose path monitoring signal range PO by the supervisory signal rewrite circuits 1211 - 1226 The SDH path is written to the multiplexer circuits 921 - 924 entered and multiplexed there. The monitoring signal input circuits 931 - 934 of the SDH part are respectively connected to the outputs of the multiplexer circuits 921 - 924 and complete the formation of SDH signals by adding monitoring signals from the SDH part, which are then sent to the SDH signal output lines 941 - 944 be issued.

Although this seventh embodiment by adding monitoring signal rewrite circuits 1211 - 1226 of the SDH path has been configured to the fourth embodiment, the same effect can be achieved also using the configurations of the fifth and sixth embodiments, wherein a switching circuit has been used by the monitoring signal rewrite circuits 1211 - 1226 of the SDH path with the outputs of the demultiplexer circuits 1031 and 1032 get connected.

Monitoring signals of the SDH path are rewritten, for example, when an error has occurred in the optical path signal coming from the signal input line 811 the optical path is input. It is envisaged that when an error occurs in the signal of the optical path, the demultiplexer circuit 911 when the VC signals output signals in which each bit is a logical "1" (see ITU-T Recommendation G.783, "Characteristics of synchronous digital hierarchy (SDH) equipment functional blocks"). Since the path monitoring signal ranges of the VC signals are not legitimate in this case, there is a possibility that the SDH network will detect the error and that the SDH network's route recovery function will work. Since the optical path network also has a path recovery function, it is desirable from the standpoint of network operation that when a fault occurs in the optical path network, paths can be restored without performing path recovery in the SDH network. Therefore, the SDH path monitoring signals can be set by the watch signal rewrite circuits of the SDH path so that no path recovery is performed in the SDH network.

18 Fig. 12 is a block diagram of an eighth embodiment of the present invention, showing an example in which the invention has been implemented in an optical path terminator in which SDH signals are input and from which a wavelength division multiplexed optical path signal is output to a wavelength division multiplexing path.

This optical path terminator includes a plurality (three in this example) of signal termination devices 1421 - 1423 the optical path for terminating the SDH signals, converting them into signals of the optical path and outputting them. The signal termination devices 1421 - 1423 of the optical path are assigned optical carriers of different wavelengths. The optical path terminator of this eighth embodiment further includes a wavelength division multiplexer circuit 1431 which are the ones from the signal termination devices 1421 - 1423 optical signals output wavelength-multiplexed and the result to the wavelength division multiplexed 1451 sends; and a route monitor signal feed-in circuit 1441 which feeds a route monitor signal into the wavelength division multiplexed optical signal selected from the wavelength division multiplexer circuit 1431 to the wavelength division multiplex 1451 Posted becomes.

In the example of this embodiment, the signal termination devices 1421 and 1422 the optical path each individual optical carriers λ1 and λ2 allocated during the signal termination devices 1423 of the optical path two optical carriers λ3 and λ4 are assigned. In this case, one can for the signal termination devices 1421 and 1422 of the optical path using the configuration shown in the first embodiment, while the configuration shown in the second or third embodiment for the signal termination devices 1423 the optical path can be used. Although this eighth embodiment shows a configuration in which plural kinds of optical path signal termination devices are used together, a configuration in which only one of the various types of optical path signal termination devices shown in the embodiments is used is feasible.

The SDH signals corresponding to the SDH signal input lines 1411 are entered by means of the signal termination devices 1421 - 1423 of the optical path accommodated in signals of the optical path. The optical carriers of the signals of the optical path are given different wavelengths, and the signals are then transmitted through the wavelength division multiplexer circuit 1431 multiplexed. The resulting wavelength-division multiplexed optical path signal then enters the link monitor signal feed circuit 1441 is entered and a route monitoring signal is fed. This path monitoring signal is an optical signal using an optical carrier having a wavelength different from wavelengths of the wavelength-multiplexed signal group of the optical path, and is for transmitting information regarding the wavelength-multiplexed signal group of the optical path to adjacent optical path terminators, and so on. In this eighth embodiment, λ0 is used as the optical carrier wavelength for the path monitoring signal.

The route monitoring signal feed circuit 1441 provides the capability of wavelength division multiplexing the link monitoring signal with the already wavelength multiplexed optical path signal group. Another possible configuration is that the wavelength division multiplexer circuit 1431 also serves as the track monitoring signal feed circuit. In either case, the signal path of the optical path and the path monitoring signal become the wavelength-division multiplex path 1451 entered.

19 Fig. 12 is a block diagram of a ninth embodiment of the present invention, showing an example in which the invention has been implemented in an optical path terminator which extracts SDH signals accommodated in a wavelength division multiplexed optical path signal inputted from a wavelength division multiplexing path , and outputs the result to SDH signal output lines.

This optical path terminator includes a plurality (three in this example) optical path terminators 1541 - 1543 for terminating the optical path signals, converting them to SDH signals and outputting them. The termination devices 1541 - 1543 of the optical path are each assigned optical carriers of different wavelengths. The optical path terminator of this ninth embodiment further includes a path monitoring signal extracting circuit 1521 extracting the route monitor signal from the wavelength division multiplexed optical signal that is from the wavelength division multiplexed link 1511 was entered; and a wavelength demultiplexer circuit 1531 comprising the wavelength division multiplexed optical signal from the wavelength division multiplexed link 1511 demultiplexed and the results to the terminators 1541 - 1543 of the optical path.

In the example of this embodiment, the signal termination devices 1541 and 1542 of the optical path assigned to individual optical carriers λ1 and λ2, respectively, during signal termination 1543 two optical carriers λ3 and λ4 are allocated. In this case, the configuration shown in the fourth or seventh embodiment for the signal termination devices 1541 and 1542 of the optical path while for the signal termination devices 1543 of the optical path, the configuration shown in the fifth or sixth embodiment can be used. Although this ninth embodiment shows a configuration in which plural kinds of optical path signal termination devices are used together, a configuration in which only one of the various types of optical path signal termination devices shown in the embodiments is used is feasible.

The wavelength-multiplexed signal group of the optical path and the path monitoring signal become the wavelength-division multiplexed link 1511 in the route monitoring signal extracting circuit 1521 entered. The route monitoring signal extracting circuit 1521 only demultiplexes the wavelength of the link monitoring signal. In this ninth Ausfüh tion form, a wavelength λ0 is assigned to the distance monitoring signal.

The optical path signal group included in the wavelength demultiplexer circuit 1531 is input, is demultiplexed by wavelength. This embodiment shows an example in which four wavelengths λ1, λ2, λ3 and λ4 were used as the multiplex wavelengths.

Although this embodiment shows a configuration in which the route monitoring signal extracting circuit 1521 and the wavelength demultiplexer circuit 1531 In the case of separate circuits, another possible configuration is to demultiplex the path monitoring signal and the optical path signal in a single wavelength demultiplexer circuit.

Each of the optical path demultiplexed signals is used in signal termination devices 1541 - 1543 entered the optical path and converted there into a SDH signal. The converted SDH signals are extracted from the SDH signal output lines 1551 output.

There the conversion between SDH signals and optical signals Way over VC signals is achieved, so it is possible a switching circuit and an SDH path monitoring signal rewrite circuit add. additionally to the signal termination function the optical path of conversion between signals of the optical Way and SDH signals, it is therefore possible a switching function between SDH signals and signals of the optical path and a Path restoration function that limits to the optical path network is to provide.

As already explained in the above was, according to the present Invention an SDH signal without change the format of the SDH signal into a signal of an optical path being transformed. Consequently, a monitoring signal of the optical path without enlargement of the signal length be fed. additionally Is it possible, a signal of the optical path between several output lines switch over and errors in the optical communication network and To handle errors in the SDH network separately. That's why it is possible, signal termination devices to realize the optical path, which finished with various service conditions can be.

Claims (16)

Optical path signal termination apparatus comprising: electrical signal termination means ( 121 - 124 . 131 - 134 . 141 ) for terminating one or more SDH signals transmitted by electrical signals and for outputting an electrical signal to be transmitted to the optical path; and characterized by terminating means ( 211 - 214 ) an optical path for inputting a monitoring signal of the optical path at the electrical level into this electrical signal, converting the resultant signal into an optical signal and outputting this signal as the signal of the optical path; wherein the means for terminating the optical path is a means ( 211 ) for inputting said optical path supervisory signal instead of the SDH signal monitoring signal included in said SDH signal having completed said electrical signal termination means. An optical path signal termination apparatus according to claim 1, wherein said electrical signal termination means comprises: means ( 121 - 124 ) for processing the SDH signal monitoring signals contained in the SDH signals; Demultiplexer ( 131 - 134 ) for demultiplexing the SDH signals processed by these means, thereby converting them into a plurality of VC signals; and a multiplexer means ( 141 ) for multiplexing the plurality of VC signals output from these demultiplexing means and converting them to AU signals by adding AU pointers, and further multiplexing the obtained plurality of AU signals and outputting an optical signal having an optical path signal format ; and said feeding means feeds the optical path supervisory signal at the electrical level with a signal format of the optical path into a predetermined range of the electrical signal. Signal termination equipment An optical path according to claim 2, wherein the predetermined range an area is the area for the monitoring signal of the SDH part in the SDH signal format equivalent. An optical path signal termination apparatus according to claim 2 or 3, wherein a plurality of terminating means ( 631 . 632 ) of the optical path are provided; Multiplexer means ( 621 . 622 ) are provided corresponding to these plural optical path termination means; and a switching circuit ( 611 ) are provided for switching signals between these multiplexing means and said demultiplexing means. An optical path signal termination apparatus according to any one of claims 2 to 4, wherein a plurality of multiplexer means ( 621 . 622 ) and several means of closure ( 631 . 632 ) of the optical path are provided and a switching circuit ( 711 ) to the Switching signals between the outputs of these multiple multiplexer means and the inputs of the plurality of optical path termination means is provided. Optical path signal termination apparatus according to any one of the preceding claims, wherein said optical path terminating means comprises means ( 213 ) for adding a monitoring signal of the optical path at the optical level to the signal of the optical path, which signal is separated from the monitoring signal of the optical path at the electrical level. An optical path signal termination apparatus according to claim 6, wherein said adding means ( 213 ) wavelength-multiplexed the optical path signal and the optical path supervisory signal at the optical level. An optical path signal terminating apparatus according to claim 6 or claim 7, wherein the optical path monitoring signal at the optical level is supplied to the optical path signal by the adding means (Fig. 213 ) is superimposed by a modulation different from the modulation of the main signal transmitted by this signal of the optical path. Signal termination devices of an optical path, comprising: termination means ( 812 - 815 ) of the optical path for receiving a signal of the optical path and converting it into an electrical signal; and characterized by electrical signal termination means ( 911 - 924 ) for converting the electrical signal output by said optical path terminating means into one or more SDH signals and outputting the same; wherein the signal of the optical path has a signal format that does not include the monitoring signal of the SDH part of the SDH signal; and the electrical signal termination means ( 931 - 934 ) which inputs a monitor signal of the SDH part in place of the optical path supervisory signal included in the optical path signal received by the optical path termination means. An optical path signal termination apparatus according to claim 9, wherein said optical path terminating means comprises means ( 814 ) which, after the optical path signal has been converted into an electrical signal, extracts the optical path monitoring signal at the electrical level added to the predetermined range of said electrical signal; and the electrical signal termination means comprise: a demultiplexer means ( 911 ) for demultiplexing the electrical signal output by the optical path termination means, thereby converting it into a plurality of VC signals; Multiplexer means ( 921 - 924 ) for multiplexing the plurality of VC signals output by said demultiplexing means and converting them to AU signals by adding AU pointers; and funds ( 931 - 934 ) for feeding monitoring signals of the SDH part into the AU signals output by said multiplexing means. An optical path signal terminating apparatus according to claim 9 or claim 10, wherein the optical path monitoring signal at the electrical level in the area of the monitoring signal of the SDH part in the SDH signal format is added to the optical path signal; the optical path termination means are configured to output an electrical signal having a signal format of the optical path, the electrical signal including this optical path monitoring signal at the electrical level; and the electrical signal termination means comprise: a demultiplexer means ( 911 ) for demultiplexing the electrical signal output by the optical path termination means (the electrical signal including the optical path supervisory signal at the electrical level), thereby converting the electrical signals into a plurality of VC signals; Medium ( 1211 - 1226 for rewriting the optical path monitoring signals at the electrical level contained in the plurality of VC signals output by said demultiplexing means; Multiplexer means ( 921 - 924 ) for multiplexing the outputs of these rewrite means and converting them to AU signals by adding AU pointers; and funds ( 931 - 934 ) for adding monitoring signals of the SDH part to the AU signals output by these multiplexing means. Optical path signal termination apparatus according to any one of claims 9 to 11, wherein a plurality of terminating means ( 1021 . 1022 ) of the optical path are provided; Demultiplexer ( 1031 . 1032 ) are provided corresponding to these plural optical path termination means; and a switching circuit ( 1041 ) are provided for switching signals between these demultiplexing means and said multiplexing means. Optical path signal termination apparatus according to any one of claims 9 to 12, wherein a plurality of closure means ( 1021 . 1022 ) of the optical path and a plurality of demultiplexing means ( 1031 . 1032 ) are provided; and a switching circuit ( 1111 ) for switching signals between the outputs of said plurality of optical path termination means and the inputs of said plurality of demultiplexer means. An optical path signal terminating apparatus according to any one of claims 9 to 13, wherein said optical path terminating means comprises means ( 812 ) for separating the optical path monitoring signal from the optical path signal at the optical level, which signal is separated from said optical path monitoring signal at the electrical level. Signal termination device of an optical path with multiple ( 1421 - 1423 Optical path signal termination apparatus according to any one of claims 1 to 8, wherein each optical path signal termination device is assigned an optical carrier having a different wavelength, and a wavelength division multiplexing means (US Pat. 1431 ) which wavelength-multiplexes the output optical signals of these optical-path signal terminators and transmits the result to the optical transmission line. Signal termination device of an optical path with multiple ( 1541 - 1543 ) Optical path signal termination apparatus according to any one of claims 9 to 14, wherein each signal termination device of the optical path is assigned an optical carrier having a different wavelength, and a wavelength demultiplexer means (Fig. 1531 ) which demultiplexes the wavelength division multiplexed optical signal from the optical transmission line and outputs the results to the optical path signal termination devices.